The paper introduces a new class of distances between nonnegative Radon measures in Rd. They are modeled on the dynamical characterization of the Kantorovich-Rubinstein-Wasserstein distances proposed by Benamou and Brenier (Numer Math 84:375–393, 2000) and provide a wide family interpolating between the Wasserstein and the homogeneous Sobolev distances of order -1.
From the point of view of optimal transport theory, these distances minimize a dynamical cost to move a given initial distribution of mass to a ﬁnal conﬁguration.
An important difference with the classical setting in mass transport theory is that the cost not only depends on the velocity of the moving particles but also on the densities of the intermediate conﬁgurations with respect to a given reference measure.
The paper studies the topological and geometric properties of these new distances, comparing them with the notion of weak convergence of measures and the well established Kantorovich-Rubinstein-Wasserstein theory. An example of possible applications to the geometric theory of gradient ﬂows is also given.

The paper introduces a new class of distances between nonnegative Radon measures in Rd. They are modeled on the dynamical characterization of the Kantorovich-Rubinstein-Wasserstein distances proposed by Benamou and Brenier (Numer Math 84:375–393, 2000) and provide a wide family interpolating between the Wasserstein and the homogeneous Sobolev distances of order -1.
From the point of view of optimal transport theory, these distances minimize a dynamical cost to move a given initial distribution of mass to a ﬁnal conﬁguration.
An important difference with the classical setting in mass transport theory is that the cost not only depends on the velocity of the moving particles but also on the densities of the intermediate conﬁgurations with respect to a given reference measure.
The paper studies the topological and geometric properties of these new distances, comparing them with the notion of weak convergence of measures and the well established Kantorovich-Rubinstein-Wasserstein theory. An example of possible applications to the geometric theory of gradient ﬂows is also given.